JP3190963U - Gas component removal sampling equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apparatus capable of adjusting the bubbling of a gas and efficiently absorbing a gas-containing component into a liquid to remove and collect the gas-containing component. SOLUTION: A first wall surface 3 is positioned and provided in a liquid storage container 2, and a second wall surface 4 is provided so as to be movable in the vertical direction so as to be able to approach and separate from the first wall surface. A manual operating means 8 for moving the second wall surface in the vertical direction outside the container is provided. A gas flow passage 50 and a gas ejection port 51 are formed between the first wall surface and the second wall surface. Gas is supplied to the flow path through the gas transport path 6 provided with the lower end communicating with the gas flow path, and the liquid is ejected from the spout portion through the flow path. By operating the operating means to move the second wall surface in the vertical direction, the width of the flow passage and the opening degree of the spout can be adjusted to adjust the size of the bubbling bubbles. [Selection diagram] Fig. 1

Description

  The present invention relates to an apparatus for removing a desired component contained in a gas by absorbing it in a liquid. More specifically, a gas-containing component removing / collecting apparatus that supplies gas to pass through the liquid and removes and collects various desired components contained in the gas while the gas passes through the liquid. About.

  2. Description of the Related Art Conventionally, there is a gas washing bottle (also called a washing bottle) as an apparatus (apparatus) that removes and collects a component contained in a gas by absorbing the component.

  As a conventional gas cleaning bottle, the one configured as shown in FIG. 12 (previous example 1) has been widely known for a long time (see, for example, Non-Patent Document 1). Hereinafter, the configuration and the like of the preceding example 1 will be described.

  As shown in FIG. 12, the gas cleaning bottle 1 of the preceding example 1 includes a liquid storage container 10 made of transparent glass for storing the liquid W, a gas supply tube 11, a gas discharge port portion 12, and a container. 10 receptacle parts 13 (female joints) are provided with glass plugs 14 (male joints) that retain (maintain) airtightness and are detachably fitted. The gas supply tube 11 is formed of a glass plug having both ends opened, and has a gas inlet 15 on the upper end side and a gas outlet 16 at the lower end of the opening.

  The plug 14 is formed of a hollow tapered plug having a taper that opens at the lower end and decreases in diameter toward the lower end. The tube body 11 is provided with a gas inlet portion 15 fixed to the top wall portion 14a of the plug body 14 by welding or the like. The gas discharge port 12 is fixed to the top wall of the plug 14 by welding or the like.

  Prior Example 1 has the above-described configuration. Next, the method of use and operation will be described. As shown in FIG. 12, a liquid W selected according to water, an aqueous solution, or other components to be collected is placed in the container 10 and stored, and the tube body 11 is placed in the liquid W to plug the plug body 14 into the receiving portion 13. Fits airtightly. Then, as shown by an arrow a in FIG. 12, when pressure is supplied from the inlet 15, the gas is supplied into the liquid W from the outlet 16 through the tube 11, passes through the liquid, and moves to the arrow. As shown by b, it is discharged from the outlet 12.

  In the above process, the gas supplied into the liquid from the outlet portion 16 of the tube body 11 forms bubbles and passes through the liquid, and a part of the components contained in the gas (desired desired) The component is absorbed by the liquid and removed.

  As described above, according to the gas cleaning bottle of the first example, the desired component contained in the gas can be absorbed and collected by the liquid. However, in the first example, since the gas is directly fed into the liquid from the outlet portion 16 of the tube body 11, it passes through the liquid as a large bubble. Therefore, since the contact area with a liquid becomes small, it has the problem that the absorption efficiency of a gas containing component is not good.

  Therefore, in order to solve the above problem, as shown in FIG. 13, a gas cleaning bottle 1A (see FIG. 13) in which a glass filter 17 is fixedly attached to the lower end of the opening of the gas supply tube 11 of the gas cleaning bottle 1 of the first example ( Prior example 2) has been proposed and is generally used (see, for example, Non-Patent Document 2).

  In the gas cleaning bottle 1A of the preceding example 2, gas is jetted into the liquid from a large number of fine openings formed in the filter 17, so that the gas is bubbled into small bubbles and passes through the liquid. Therefore, since the contact area with the gas liquid becomes large and the contact time with the liquid becomes long, the absorption efficiency of the gas-containing component can be improved as compared with the first example. However, the prior example 2 has a problem that the filter 17 is likely to be clogged, and in the case that the filter 17 is clogged, there is a problem that the work for correcting the clogging by washing or the like is complicated and takes time and labor. The preceding example 2 is configured in the same manner as the preceding example 1 except that the glass filter 17 is attached to the lower end of the tubular body 11, and therefore, the same components are denoted by the same reference numerals and the description thereof is omitted. .

  As described above, according to the preceding example 2, gas can be generated in small bubbles to increase the contact area with the liquid and the contact time can be increased, thereby improving the efficiency of absorbing and removing gas-containing components. Can do. However, the prior example 2 has a problem that the filter is easily clogged. However, no technology that can solve this problem has been proposed yet.

  By the way, when the component contained in the gas is absorbed and collected by the liquid, depending on the type of the component, the size of the gas bubble (bubble) is passed through the liquid in a large state as in the preceding example 1. Even in this case, the components in the gas may be efficiently absorbed and removed by the liquid. In such a case, the preceding example 1 can suppress the increase in the pressure resistance value on the gas supply side compared to the preceding example 2, so that the gas supply energy can be reduced and the gas-containing component absorption processing time can be reduced. There are cases where it can be shortened. Therefore, it is desirable to be able to adjust the size of the gas bubbles.

  As described above, it can be said that it is ideal to eliminate the problems of the glass filter of the prior example 2 and to adjust the gas bubbling. Therefore, development of the technology is demanded in this industry. However, such a technique has not been proposed yet.

Article about washing bottles on Kiriyama Seisakusho (applicant company) website Article about washing bottles on the website of Kiriyama Seisakusho Co., Ltd. (applicant company)

  The present invention has been made in view of the above-described circumstances, and solves the problems of the glass filter of the preceding example 2 and is configured so that gas bubbling can be adjusted, so that the gas-containing component can be efficiently converted into a liquid. An object of the present invention is to provide a gas-containing component removal and collection device that can be removed and collected by absorption.

In order to achieve the above object, one of the present inventions (first invention) is to supply a gas to a liquid and allow the liquid to pass a desired component contained in the gas. A gas component removal sampling device that absorbs and removes,
A liquid storage container having a desired volume for storing and storing a desired amount of liquid;
A first wall surface positioned and provided in the container;
A second wall surface that is movable in the vertical direction in the container, and provided so as to be able to approach and separate from the first wall surface by the vertical movement;
A gas flow path formed between the first and second walls and an outlet part of the gas flow path, and an annular gas jet part for jetting the gas into the liquid in the container; Bubbling generation adjusting means arranged at a position near the bottom side as much as possible of the bottom half side in the container or the lower half of the container;
A gas inlet on the upper end side, a lower end connected to the gas flow path, and a gas transport path for transporting the gas to the gas flow path;
A gas discharge port provided in communication with the upper end side in the container;
Manual operation means for moving up and down the second wall surface by manual operation outside the container;
And
The second wall surface is moved up and down by the operating means, and the passage width of the gas flow passage and the opening degree of the gas outlet are adjusted in synchronization. It is.

  If comprised as mentioned above, the magnitude | size of a bubble is arbitrarily adjusted by moving a 2nd wall surface to an up-down direction by manual operation, and changing the passage width of the said gas passage, and the opening degree of the said gas ejection part. be able to.

Another device of the present invention (second device) is a gas-containing component removing and sampling device of the first device, wherein the first wall surface is formed on a bottom wall portion of the container,
The second wall surface has the gas inlet portion on the upper end side of the tube, and is disposed with the gas inlet portion positioned outside the container and the lower end portion facing the bottom side in the container, It is formed in a movable member provided to be fixed to the lower end of a movable tube body for gas transportation provided so as to be movable in the vertical direction in the container and removable from the container,
The movable tube body is manually moved up and down by the operation means to adjust the passage width of the gas flow passage and the opening of the gas outlet.

Still another device of the present invention (third device) is the gas-containing component removing and sampling device of the first and second devices, wherein the first wall surface is recessed in a hemispherical shape at the bottom wall portion of the container. Consists of a concave spherical wall surface formed of
The movable member has a hemispherical convex spherical surface that fits and fits into the concave spherical surface,
The second wall surface is constituted by a convex spherical wall surface of the convex spherical surface of the movable member.

  In the third device described above, the concave spherical wall surface and the convex spherical wall surface may be formed by finely sanding substantially the entire surface of both the wall surfaces by, for example, polishing with a desired number of sandpaper or the like, such as by rubbing. A configuration in which the surface is formed on a rough surface (finely machined surface) such as an eye can be employed. Moreover, the structure which provides the slit-shaped groove | channel radially provided at the said both wall surface or any one wall surface at substantially equal intervals is employable.

Still another device of the present invention (fourth device) is the gas-containing-component removing / collecting device of the first and second devices, wherein the first wall surface has a horizontal bottom wall portion of the container. It consists of a horizontal upper wall formed by processing,
The movable member has a horizontal lower wall surface formed by processing the lower surface in a horizontal shape so as to approach and separate while maintaining a parallel posture with respect to the horizontal upper wall surface,
The second wall surface is constituted by the horizontal lower wall surface of the movable member.

  In the fourth device, the upper wall surface and the lower wall surface can adopt the same structure as that of the third device formed on a rough surface (a finely machined surface).

Still another device of the present invention (fifth device) is the gas-containing component removing and sampling device of the first device, wherein the gas inlet portion is provided on the upper end side of a tube having an open lower end, and the gas A gas transport tube body that has an inlet portion positioned outside the container and has a lower end portion positioned at a desired position on the bottom side in the container so that it can be attached to and detached from the container and can be fixed at a fixed position; ,
A movable housing provided to be movable in the vertical direction while forming a cylindrical gap for forming a gas transport passage between the inner wall surface of the tubular body and penetrating the tubular body;
The first wall surface is formed on a fixing member provided to be fixed to the lower end of the gas transport tube,
The second wall surface is formed on a movable member provided to be fixed to a lower end of the movable casing,
The movable housing is manually moved up and down by the operation means to adjust the passage width of the flow passage and the opening of the gas outlet.

Still another device of the present invention (sixth device) is the gas-containing-component removing / collecting device according to the first and fifth devices, wherein the fixing member has an upper end at the lower end of the gas transport tube. And having a generally inverted conical fixed cylindrical body having an inverted conical tapered outer wall surface with a taper that is gradually reduced in diameter from the upper end side toward the lower end.
The first wall surface is configured by the tapered outer wall surface of the fixed cylindrical body,
The movable member has a substantially inverted conical movable cylinder having an inverted conical tapered inner wall surface that closes the lower end side and opens the upper end and fits and fits the tapered outer wall surface of the fixed cylindrical body. Configured with a body,
The second wall surface is constituted by the tapered inner wall surface of the movable cylindrical body.

  In the sixth invention, the tapered outer wall surface and the tapered inner wall surface can adopt a configuration in which the same rough surface as that of the third invention is formed. Moreover, the structure which provides the arbitrary number of slit-shaped groove | channels formed in the said both wall surface or any one wall surface at substantially equal intervals toward the longitudinal direction (up-down direction) is employable.

According to still another aspect of the present invention (seventh aspect), in the gas-containing component removal and sampling apparatus according to the first and fifth aspects, the fixing member has an upper end communicating with the gas transport tube. And having a substantially conical fixed cylindrical body having a conical tapered inner wall surface with a taper that opens at the lower end and gradually increases in diameter from the upper end side toward the lower end.
The first wall surface is constituted by the tapered inner wall surface of the fixed cylindrical body,
The movable member is configured to have a substantially conical movable conical body having a conical tapered outer wall surface that closes an upper end portion and fits and fits into the tapered inner wall surface of the fixed cylindrical body. ,
The second wall surface is constituted by a tapered outer wall surface of the movable conical body.

  In the seventh invention, the tapered inner wall surface and the tapered outer wall surface may adopt a configuration formed on a rough surface similar to that of the sixth invention. Moreover, the structure which provides the arbitrary number of slit-shaped groove | channels formed in the said both wall surface or any one wall surface at substantially equal intervals toward the longitudinal direction (up-down direction) is employable.

Still another device of the present invention (eighth device) is the gas-containing component removal and sampling device according to the first and fifth devices, wherein the fixing member is formed by processing the bottom surface horizontally. A fixed plate-like body of a desired size having a lower wall surface,
The first wall surface is constituted by the horizontal lower wall surface of the fixed plate-like body,
The movable member has a movable plate-like body having a horizontal upper wall surface formed by processing the upper surface in a horizontal shape so as to approach and separate while maintaining a parallel posture with respect to the horizontal lower wall surface. Configured
The second wall surface is constituted by the horizontal upper wall surface of the movable plate-like body.

  In the eighth device, the lower wall surface and the upper wall surface can adopt the same structure as that of the fourth device.

The present invention has the following effects.
(1) The problem of clogging of the glass filter of the preceding example 2 can be solved.
(2) The apparatus can be easily cleaned.
(3) By operating the manual operation means outside the container and moving the second wall surface in the vertical direction, the passage width of the gas flow passage and the opening of the gas outlet are adjusted, and the size of the bubble The thickness can be easily adjusted to a desired size. That is, the bubbling performance can be easily adjusted, and the gas-containing component can be efficiently absorbed into the liquid to be removed and collected.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory longitudinal sectional view schematically showing an overall configuration of a gas-containing component removal sampling apparatus according to an embodiment of the present invention. FIG. 2 is an explanatory vertical cross-sectional view schematically showing a configuration of a part of the upper half side of the apparatus in FIG. 1 in an enlarged manner. FIG. 2 is an enlarged view of a part of the lower half portion side of the apparatus in FIG. 1 and schematically shows the configuration thereof, in which FIG. 1 (a) is an explanatory longitudinal sectional view of the apparatus, and FIG. An explanatory side view showing a hemispherical convex spherical surface provided at a part of the movable movable body for transportation and the lower end of the movable tubular body, and FIG. 10C is a sectional view taken along line AA in FIG. is there. FIG. 2 is an explanatory diagram showing a usage state of the device of FIG. It is a figure which shows schematically the structure of the principal part of the gas containing component removal sampling device of other embodiment of this invention, Comprising: The figure (a) is an explanatory longitudinal cross-sectional view of the said apparatus, The figure (b) is gas. The explanatory side view which shows the hemispherical convex spherical surface provided in the lower end of the movable tube for transportation, The figure (c) is a BB line explanatory sectional view of the figure (a). It is explanatory longitudinal cross-sectional view which shows schematically the structure of the principal part of the gas containing component removal sampling apparatus of further another embodiment of this invention. It is explanatory longitudinal cross-sectional view which shows roughly the whole structure of the gas containing component removal sampling device of further another embodiment of this invention. FIG. 8 is an explanatory longitudinal cross-sectional view schematically showing a configuration of a part of the upper half side of the apparatus in FIG. 7 in an enlarged manner. FIG. 8 is an enlarged view of a part of the lower half portion side of the apparatus of FIG. 7 and schematically showing the configuration thereof, in which FIG. (A) is an explanatory longitudinal section showing the configuration of the first and second wall surface portions FIG. 2B is an explanatory side view showing the configuration of the first wall surface portion, and FIG. 2C is an explanatory longitudinal sectional view showing the configuration of the second wall surface portion. It is explanatory longitudinal cross-sectional view which shows schematically the structure of the principal part of the gas containing component removal sampling apparatus of further another embodiment of this invention. It is a figure which shows schematically the structure of the principal part of the gas containing component removal sampling device of further another embodiment of this invention, Comprising: The same figure (a) is a description longitudinal cross-sectional view of the said apparatus, The same figure (b) is FIG. FIG. 5 is an operation explanatory view showing first and second wall surfaces of the device. It is explanatory longitudinal cross-sectional view which shows roughly the structure of the conventional gas content component removal collection apparatus (gas washing bottle). It is an explanatory longitudinal section showing roughly the composition of other conventional gas content ingredient removal sampling devices.

  Hereinafter, an example of an embodiment of the present invention will be described with reference to the drawings.

  1 to 4 show a gas-containing component removal sampling apparatus according to an embodiment (Embodiment 1) of the present invention.

  As shown in FIGS. 1 to 4, the gas component removal sampling apparatus 100 according to the first embodiment includes a liquid storage container 2, a first wall surface 3, a second wall surface 4, a bubbling generation adjusting unit 5, and a gas inlet part. A gas transport path 6, a gas discharge port 7, and manual operation means 8.

  The container 2 accommodates (puts in) a desired amount of the desired liquid W and stores it, and adopts a desired volume. The container 2 is made of, for example, a glass or other material having chemical resistance. The container 2 of the first embodiment employs a transparent glass container.

  The volume (size) of the container 2 is not particularly limited, and can be arbitrarily determined according to the application and the like, and examples thereof include a range of about 100 mL to 1000 mL. However, it is not limited to the above range.

  The container 2 of the first embodiment is formed in a vertically long cylindrical shape having a bottom end (bottom) of the cylindrical portion 20 closed with a bottom wall portion 21 and having a receiving port 22 at the upper end. A screw groove 23 (male screw) is provided on the outer peripheral wall surface of the receiving portion 22. Moreover, the base part 24 for stands for installing the container 2 upright is provided in the lower end part of the container 2 of Embodiment 1. FIG. In addition, the said base part 24 is provided as needed, and there are some which are not provided with the base part 24. FIG.

  A screw cap 80 having a screw groove 82 (female screw) that is screwed into the screw groove 23 of the receiving portion 22 is provided on the inner peripheral wall surface of the cylindrical shape 81 by being screwed to the receiving portion 22 of the container 2. It is configured. The cap 80 constitutes a turning operation part of the manual operation means 8. This point will be further described later.

  The first wall surface 3 is positioned and provided in the container 2. The first wall surface 3 of the first embodiment is configured by a concave spherical wall surface 30 formed by denting the bottom wall portion 21 of the container 2 into a hemispherical shape. Further, the concave spherical wall surface 30 of the first embodiment is polished by using a sand paver or the like having a desired roughness (number), such as a rubbing process of a joint part of a physicochemical glass instrument. A configuration is adopted in which substantially the entire wall surface 30 is formed on a rough surface 31 (a finely slid surface) such as a fine grained shape.

  The second wall surface 4 is provided so as to face the first wall surface 3 so as to be movable in the vertical direction within the container 2 and to be able to approach and separate from the first wall surface 3 by the vertical movement.

  The second wall surface 4 of the second embodiment has a gas inlet 62 on the upper end side of a pipe 61 having a predetermined length, is arranged with the lower end facing the bottom side in the container 2, and moves up and down in the container 2. It is formed in a movable member 40 that is fixedly attached to the lower end of a movable tube body 60 for gas transportation that is movable in the direction and removable from the container 2. The movable tube 60 constitutes the gas transport path 6. This point will be further described later.

  The movable member 40 of the first embodiment has a hemispherical convex spherical surface that fits and fits into the concave spherical wall surface 30 of the first wall surface 3, for example, like a spherical bearing or a ball joint. The wall surface 4 is constituted by the convex spherical wall surface 41 of the convex spherical surface. In the convex spherical wall surface 41 of the first embodiment, the entire surface of the wall surface 30 is formed into a rough surface 42 (a minute sliding surface) such as a fine grain shape by the same processing as the first concave spherical wall surface 30. The structure to form is adopted.

  The bubbling generation adjusting means 5 is formed by a gas flow passage 50 formed between the first wall surface 3 and the second wall surface 4 and an outlet portion of the flow passage 50, and gas is contained in the liquid W in the container. And an annular gas ejection port 51 to be ejected. The bubbling production adjusting means 5 is arranged at a position near the possible bottom side of the bottom side in the container 2 or the lower half of the container.

  The bubbling generation adjusting means 5 of Embodiment 1 includes a gas flow passage 50 formed between the concave spherical wall surface 30 of the first wall surface and a convex spherical wall surface 41 of the second wall surface, and an outlet portion of the flow passage 50. And a circular annular gas outlet 51. As a result, the gas passes through the flow passage 50 and is jetted out into the fluid from the jet port 51. The gas is bubbled up and passes through the liquid, but the size of the bubble (bubble) of the bubbling depends on the passage width of the flow passage 50 and the opening of the spout 51, and the bubble is larger than the minute bubble. In this way, it can be adjusted steplessly.

  The apparatus 100 according to the present embodiment includes an attachment portion 70 that is attached to the cap 80 so as to move integrally with the cap 80 in an integrated manner. The attachment part 70 of Embodiment 1 is comprised with the transparent glass material.

  As shown in detail in FIG. 2, the mounting portion 70 of the first embodiment is fixed to a lower end of the main body 71 and a main body 71 that is formed to have a diameter larger than the inner diameter of the receiving portion 22 of the container 2 and that is hollow inside. And a cylindrical tubular plug 72 having a desired length that is inserted into the receiving portion 22. The lower end of the plug 72 is opened (opening 73).

  The attachment portion 70 is provided by penetrating the plug 72 through a hole (not shown) provided in the center portion of the top wall portion 83 (top wall portion) of the cap 80. On the outer peripheral wall surface at a desired part (near the lower end in the drawing) of the plug body 72, a sealing rubber material or the like that fits the plug body 72 slidably while maintaining airtightness in the receiving portion 22 is used. An O-ring 84 (O-ring) made of an elastic material is provided. The attachment portion 70 allows the plug body 72 to penetrate the top wall portion 83 and the lower end portion of the main body 71 is in contact with the upper surface of the top wall portion 83 so that the O-ring 84 and the top wall portion of the plug body 72 are in contact with each other. A fixing ring 85 is fitted between the lower surface of 83 and fixedly mounted. Accordingly, the cap body 72 is slid while maintaining airtightness by rotating the cap 80 left and right (forward and reverse) in a state where the plug body 72 of the mounting portion 70 is screwed into the receiving portion 22. However, the mounting portion 70 is configured to be movable in the vertical direction.

  Thus, the movable tube body 60 for transporting the gas causes the gas inlet portion 62 to protrude from the top wall portion of the main body 71 of the mounting portion 70 to the outside of the main body 71 and the tube 61 to be positioned at the center of the mounting portion 70. The upper end portion of the pipe 61 is fixed to the top wall portion of the main body 71 in an airtight manner by welding or the like and attached to the attachment portion. A gas transport path 6 is constituted by the movable tube body 60. Further, the gas discharge port portion 7 is provided so that the base end portion thereof communicates with the inside of the main body 71 and protrudes from the main body 71.

  The gas-containing component removal sampling apparatus 100 according to Embodiment 1 is configured as described above. Next, a method of using the device 100 according to the first embodiment, operational effects, and the like will be described.

  A desired amount of the desired liquid W is placed in the liquid storage container 2. As the liquid W to be used, for example, water, alkaline aqueous solution, concentrated sulfuric acid or other liquid is selected and adopted depending on the type of components removed from the gas. This is the same as in the prior art.

  Next, the movable tube body 60 is inserted into the container 2 from the lower end side, the plug body 72 is inserted into the receiving portion 22, and the cap 80 is screwed into the receiving portion 22. Next, the cap 80 is manually rotated, and the movable member 40 is lowered through the pipe 61 so that the convex spherical wall surface 41 is fitted to the concave spherical wall surface 30, and the first wall surface 3 and the second wall surface 4 The passage width of the gas flow passage 50 formed between them and the opening of the gas outlet 51 are adjusted.

  Then, as shown in FIG. 4, the other end of the gas supply hose 65 whose one end is connected to a gas supply part (not shown) is connected to the gas inlet part 62. In addition, one end of a gas exhaust hose 75 is connected to the gas exhaust port 7 and the other end of the hose 75 is connected to an exhaust processing unit (not shown) or opened to the atmosphere. Preparation is completed by the above.

  Therefore, when gas is supplied under pressure in the above state, the gas is supplied from the lower end of the pipe 61 to the gas flow passage 50 through the gas transport path 6 constituted by the movable tube body 60, and this gas is supplied from the gas outlet 51. The liquid W is sequentially ejected into the liquid W, passes through the liquid, and is discharged from the discharge port 7 through the gap between the plug 72 and the pipe 61 and the hollow portion of the main body 71.

  In the above process, the gas ejected into the liquid from the spout 51 is bubbled and passes through the liquid as bubbles B (bubbles), and the gas bubbles B come into contact with the liquid W during this passage. Desired components contained in the gas are absorbed and removed by the liquid.

  And according to Embodiment 1, by rotating the cap 80 and moving the second wall surface in the vertical direction, the passage width of the gas flow passage 50 and the opening degree of the gas outlet 51 can be adjusted. The size of the bubble B of the bubbling can be arbitrarily adjusted. Therefore, it is possible to easily adjust the bubbling generation function and efficiently absorb the desired gas-containing component into the liquid for removal and collection.

  Further, by rotating the cap 80 to release the screwing with the receiving portion 22, the movable tube body 60 for gas transportation and the mounting portion 70 can be integrally taken out from the container 2, so that the cleaning operation of each portion can be performed. Easy to do. Furthermore, the assembly work can be easily performed.

(Effect of Embodiment 1)
According to the first embodiment, the following operational effects are obtained.
(1) Bubbling can be adjusted steplessly by rotating the screw cap.
(2) According to the above (1), the gas-containing component can be efficiently absorbed and collected by the liquid.
(3) The cleaning operation of each component can be easily performed.
(4) The apparatus can be easily assembled.

  FIG. 5 shows a gas-containing component removal sampling apparatus according to another embodiment (Embodiment 2) of the present invention. In the second embodiment and each embodiment disclosed below, the same reference numerals are given to the same components as those already described in the first embodiment, and the description thereof will be omitted.

  The gas-containing component removal sampling apparatus 200 according to the second embodiment is characterized by the configuration of the second wall surface.

  The second wall surface 4A of the device 200 according to the second embodiment has a plurality of slit-shaped grooves 42a... 42a on a convex spherical wall surface 41 configured in the same manner as in the first embodiment and hung from the distal end side to the proximal end of the wall surface 41. Is formed in a convex spherical wall surface provided with the groove 42a. Each groove 42a is narrow and formed in a shallow bottom. Other configurations are the same as those of the first embodiment.

  The gas-containing component removal sampling apparatus 200 according to the second embodiment is configured as described above, and is used in the same manner as in the first embodiment, and has the same effects as those in the first embodiment.

  FIG. 6 shows still another embodiment (Embodiment 3) of the present invention. The gas-containing component removal sampling apparatus 300 according to the third embodiment is characterized by the configuration of the first wall surface and the second wall surface.

  The apparatus 300 according to the third embodiment includes a horizontal upper wall surface 30A formed by processing the upper surface of the bottom wall portion 21A of the liquid storage container 2 into a horizontal shape. The first wall surface 3A is composed of the upper wall surface 30A.

  In addition, the movable member 40A of the third embodiment is configured by a flat plate-shaped movable member 40A such as a circular plate in place of the movable member 40 of the first embodiment. The flat plate-shaped movable member 40A is formed on a horizontal lower wall surface 41A formed by processing the lower surface in a horizontal shape so as to approach and separate while maintaining a parallel posture with respect to the horizontal upper wall surface 30A. It is. The second wall surface 4A is constituted by the lower wall surface 41A.

  The gas flow passage 50 and the gas outlet 51 of the bubbling generation adjusting means 5 of Embodiment 3 are configured between the upper wall surface 30A of the first wall surface 3A and the lower wall surface 41A of the second wall surface 4A. Yes. Although not shown, the upper wall surface 30A and the lower wall surface 41A can adopt a configuration in which they are formed on the same rough surface (fine sliding surface) as in the first embodiment. Moreover, the structure which provides the slit-shaped groove | channel similar to Embodiment 2 to the said upper wall surface 30A and / or lower wall surface 41A is employable. Other configurations are the same as those of the first embodiment.

  The gas-containing component removal sampling apparatus 300 according to the third embodiment is configured as described above, and is used in the same manner as in the first embodiment, and has the same effects as those in the first embodiment.

  7 to 9 show a gas component removal sampling apparatus according to still another embodiment (Embodiment 4) of the present invention.

  A gas-containing-component removing / collecting device 400 according to the fourth embodiment includes an attachment portion 70A that is removably attached to the receiving portion 22A of the liquid storage container 2, and a gas transport tube 60A that is provided to be fixed to the attachment portion 70A. And a movable casing 9 that penetrates the tubular body 60A and is movable in the vertical direction.

  70 A of attachment parts are formed in the inside hollowly, and are equipped with the taper plug 76 which can be inserted / removed to the receiving-portion part 22A in the lower half part side, and is airtightly inserted (inserted). The lower end of the taper plug 76 is opened (opening 77). The upper end portion of the attachment portion 70 </ b> A is closed with a top wall 78. As described above, the attachment portion 70A is detachably attached to the receiving portion 22A of the container 2 by being hermetically inserted.

  The gas transport pipe 60A has a pipe 66 having a predetermined length with its lower end opened, and a fixing member 67 is fixedly provided on the lower end of the pipe 66. The fixing member 67 of the fourth embodiment has a substantially inverted conical shape in which an upper end portion is communicated with the inside of the tube 66 of the tube body 66A, a lower end is opened, and a taper is gradually reduced from the upper end portion side toward the lower end. A fixed cylindrical body 68 is provided.

  The first wall surface 3 </ b> B of the fourth embodiment is configured by a tapered outer wall surface 68 a of the fixed cylindrical body 68. The tapered outer wall surface 68a of the fourth embodiment is formed on a rough surface 31 (a fine sliding surface) processed in the same manner as in the first embodiment.

  The tube body 60A (tube 66) is formed to have a desired diameter and a predetermined length. The length of the tubular body 60A will be described later. The tube body 60 is provided with the upper end portion side of the tube 66 protruding upward from the top wall 78 of the mounting portion 70A, and a desired portion on the upper end portion side is fixed to the top wall 78 by welding or the like. In this case, the tubular body 60A is provided at the center of the mounting portion 70A.

  The length of the tubular body 60A (tube 66) is such that the lower end of the fixed cylindrical body 68 is at a desired position on the bottom side in the container 2 when the tapered plug body 76 is airtightly inserted into the receiving portion 22A. The length is set so that it can be positioned.

  The gas inlet portion 62A of the fourth embodiment is positioned at a desired portion in a portion projecting upward from the top wall 78 of the mounting portion 70A of the tube body 60A, and the proximal end is communicated with the inside of the tube body 60A to be fixed. It is provided. Thereby, the gas is configured to be introduced into the pipe body 60A from the inlet portion 62A.

  A thread groove 23A (male screw) is provided on the outer peripheral wall surface of the upper end portion of the tube body 60A (tube 66). Then, a screw cap 80A having a screw groove 82A (female screw) that is screwed onto the inner peripheral wall surface of the cylindrical body 81A and screwed into the screw groove 23A of the tube body 60A is provided at the upper end portion of the tube body 60A. It is configured. The cap 80A includes a top wall portion 83A at the upper end.

  The movable casing 9 is made of a pipe material having a predetermined length. The movable casing 9 is arranged coaxially with the pipe body 60A (pipe 66) and arranged with a cylindrical gap 90 for forming a gas transport passage between the pipe body 60A and the inner wall surface of the pipe body 60A. The body 60A is pierced and movable in the vertical direction.

  The housing 9 is provided at a desired position above the attachment position of the inlet portion 62A, and is made of an elastic material or the like that seals between the outer peripheral wall surface of the housing 9 and the inner wall surface of the gas transport tube body 60A. An O-ring 91 (O-ring) is provided. Thereby, while the upper end part side of the space | gap part 90 is obstruct | occluded with the O-ring 91, the housing 9 is comprised so that it can move to an up-down direction, maintaining airtightness.

  The housing 9 includes a movable member 40B that is fixed to the lower end.

  As shown in detail in FIG. 9, the movable member 40 </ b> B according to the fourth embodiment closes the lower end portion with the bottom wall 43 and opens the upper end, and fits and fits to the tapered outer wall surface 68 a of the fixed cylindrical body 68. The movable cylindrical body 45 having a generally inverted conical shape having an inverted conical tapered inner wall surface 44 that can be fitted is configured. The movable member 40B is provided with a bottom wall 43 fixed to the lower end of the housing 9 by welding or the like.

  The second wall surface 4 </ b> B of the fourth embodiment is configured by the tapered inner wall surface 44. The tapered inner wall surface 44 of the fourth embodiment is formed on a rough surface 42 (a fine sliding surface) processed in the same manner as in the first embodiment.

  The bubbling generation adjusting means 5 of the fourth embodiment includes a gas flow path 50 formed between the tapered outer wall surface 68a of the first wall surface 3B and the tapered inner wall surface 44 of the second wall surface 4B. And a circular annular gas jet part 51 of the outlet part. Thereby, the gas passes through the flow passage 50 and is configured to be ejected from the ejection port portion 51 into the fluid in a circular shape.

  The movable housing 9 is fixedly attached to the cap 80A so as to move in synchronization with the cap 80A.

  As shown in detail in FIG. 8, the movable housing 9 of the fourth embodiment includes annular flanges 92 and 93 provided on the upper end side of the housing 9 with a desired interval. And the upper end part of the housing 9 is protruded from the hole (a code | symbol is not shown) opened in the center part of the top wall part 83A of the cap 80A, and between the flange 92 and the upper surfaces of the top wall part 83A, and the flange 93, A configuration is adopted in which the casing 9 is fixed and attached to the cap 80A with packings 94 and 95 interposed between the lower surfaces of the top wall 83A.

  The gas discharge port portion 7A of the fourth embodiment is provided at a desired portion of the top wall 78 of the mounting portion 70A with a proximal end communicating with the hollow interior of the mounting portion 70A and fixed by welding or the like. Thereby, the gas that has passed through the liquid in the container is configured to be discharged from the gas discharge port portion 7A.

  With the above configuration, when the cap 80A is manually rotated, the movable casing 9 moves in the vertical direction, so the movable member 40B also moves in the vertical direction in synchronization. Thereby, the gas formed between the first wall surface and the second wall surface is configured to adjust the passage width of the flow passage 50 and the opening degree of the gas outlet 51.

  The gas-containing component removal sampling apparatus 400 of Embodiment 4 has the above-described configuration. Then, after putting a desired amount of liquid into the container 2, as shown in FIG. 7, the taper plug of the mounting portion 70A is air-tightly inserted and set in the receiving portion 22A, and the same as in the first embodiment. It is used for Thereby, there exists an effect similar to Embodiment 1.

  FIG. 10 shows still another embodiment (Embodiment 5) of the present invention. The gas-containing component removal sampling apparatus 500 of Embodiment 5 is characterized by the configuration of the first wall surface and the second wall surface.

  The fixing member 67A of the device 500 of the fifth embodiment replaces the fixing member 67 of the fourth embodiment with the upper end communicating with the gas transport tube 60A and opens the lower end, gradually from the upper end side toward the lower end. It has a substantially conical fixed cylindrical body 68A having a conical tapered inner wall surface 44A with a tapered diameter.

  The first wall surface (reference numeral is omitted) of the fifth embodiment is configured by a tapered inner wall surface 44A of a fixed cylindrical body. The tapered inner wall surface 44A of the fifth embodiment is formed of a rough surface (reference numeral is omitted) processed in the same manner as in the first embodiment.

  Further, the movable member 40C of the fifth embodiment replaces the movable member 40B of the fourth embodiment and is fixed to the movable casing 9 with the upper end closed, and is fitted and fitted to the tapered inner wall surface 44A of the fixed cylindrical body 68A ( It has a substantially conical movable conical body 69 having a conical tapered outer wall surface 69a to be fitted.

  The second wall surface (the symbol is omitted) of the fifth embodiment is configured by a tapered outer wall surface 69 a of the movable conical body 69. The tapered outer wall surface 69a of the fifth embodiment is formed on a rough surface (reference numeral is omitted) processed in the same manner as in the first embodiment.

  The bubbling generation adjusting means 5 according to the fifth embodiment is formed between the tapered inner wall surface 44A of the fixed cylindrical body 68A of the first wall surface and the tapered outer wall surface 69a of the movable conical body 69 of the second wall surface. It has a gas flow path and a gas outlet part of the outlet part of the flow path. Thereby, the gas passes through the flow path and is configured to be ejected in a circular shape from the ejection port portion into the liquid. Other configurations are the same as those of the fourth embodiment.

  The gas-containing-component removing / collecting apparatus 500 according to the fifth embodiment is configured as described above, and is used in the same manner as in the fourth embodiment, and has the same effects as the fourth embodiment.

  FIG. 11 shows still another embodiment (Embodiment 6) of the present invention. The gas-containing component removal sampling apparatus 600 of Embodiment 6 is also characterized by the configuration of the first wall surface and the second wall surface.

  The fixing member 67B of the apparatus 600 of the sixth embodiment is a circular flat plate of a desired size having a horizontal lower wall surface 44B formed by processing the lower surface horizontally, instead of the fixing member 67 of the fourth embodiment. The fixed plate-like body 96 is configured. The plate-like body 96 has a gas circulation hole 97 having the same diameter as the inner diameter of the lower end of the opening of the tube body 60A for gas transportation at the center. Gas is introduced into the gas flow passage 50 from the hole.

  The first wall surface 3C of the sixth embodiment is configured by the horizontal lower wall surface 44B. In addition, the said lower wall surface 44B of Embodiment 6 is formed with the rough surface (code | symbol is abbreviate | omitted) processed similarly to Embodiment 1. FIG.

  The movable member 40D of the apparatus 600 according to the sixth embodiment has a horizontal upper wall formed by processing the upper surface horizontally so as to approach and leave the horizontal lower wall 44B while maintaining a parallel posture. It has a movable plate-like body 98 such as a circular flat plate having 45B. Both the plate-like bodies 96 and 98 are formed in substantially the same size. In addition, the said upper wall surface 45B of Embodiment 6 is formed with the rough surface (a code | symbol is abbreviate | omitted) similar to the above.

  The bubbling generation adjusting means 5 of the sixth embodiment includes a gas flow path 50 and a flow formed between the horizontal lower wall surface 44B of the first wall surface 3C and the horizontal upper wall surface 45B of the second wall surface 4C. It has a gas outlet 51 at the outlet of the passage 50. Thereby, the gas passes through the flow passage 50 and is configured to be ejected from the ejection port portion 51 into the liquid in an annular shape. Other configurations are the same as those of the fourth embodiment.

  The gas-containing component removal sampling apparatus 600 according to the sixth embodiment is configured as described above, and is used in the same manner as in the fourth embodiment.

  In each of the above embodiments, an example in which one set of the gas-containing component removal and sampling apparatus of the present invention is provided is disclosed, but a plurality of sets of the apparatuses can be arranged and used. When a plurality of sets of the devices are arranged, for example, the gas discharge port portion of the device on the upstream side and the gas inlet portion of the device on the downstream side can be connected and used. By adopting this method, the components contained in the gas can be absorbed and collected by the liquid in each container of each device. Moreover, the said apparatus of this invention can be used also as a vacuum system.

  In addition, the gas-containing component removal and sampling apparatus of each embodiment described above is disclosed as an example, and the present invention is not limited to the above-described embodiment, and the technical idea described in the claims of the utility model registration is not exceeded. It can be arbitrarily changed within the range.

2 Liquid storage container 3 First wall surface 4 Second wall surface 5 Bubbling generation adjusting means 6 Gas flow passage 7 Gas discharge port portion 8 Manual operation means 9 Movable housing 30 Concave spherical wall surface 40 Concave spherical wall surface 60 Movable tube for gas transportation Body 80 Screw cap

Claims (8)

A gas-containing component removal and sampling device that supplies gas to a liquid and passes the liquid through the liquid and absorbs and collects a desired component contained in the gas.
A liquid storage container having a desired volume for storing and storing a desired amount of liquid;
A first wall surface positioned and provided in the container;
A second wall surface that is movable in the vertical direction in the container, and provided so as to be able to approach and separate from the first wall surface by the vertical movement;
A gas flow path formed between the first and second walls and an outlet part of the gas flow path, and an annular gas jet part for jetting the gas into the liquid in the container; Bubbling generation adjusting means arranged at a position near the bottom side as much as possible of the bottom half side in the container or the lower half of the container;
A gas inlet on the upper end side, a lower end connected to the gas flow path, and a gas transport path for transporting the gas to the gas flow path;
A gas discharge port provided in communication with the upper end side in the container;
Manual operation means for moving up and down the second wall surface by manual operation outside the container;
And
A gas configured to adjust the passage width of the gas flow passage and the opening of the gas outlet in synchronization by moving the second wall surface in the vertical direction by the operating means. Contained component removal sampling device. In the gas content ingredient removal sampling device according to claim 1,
The first wall surface is formed on a bottom wall portion of the container;
The second wall surface has the gas inlet portion on the upper end side of the tube, and is disposed with the gas inlet portion positioned outside the container and the lower end portion facing the bottom side in the container, It is formed in a movable member provided to be fixed to the lower end of a movable tube body for gas transportation provided so as to be movable in the vertical direction in the container and removable from the container,
Gas-containing component removal characterized in that the movable tube body is manually moved up and down by the operating means to adjust the passage width of the gas flow passage and the opening of the gas outlet. Collection device. In the gas content ingredient removal sampling device according to claim 2,
The first wall surface is constituted by a concave spherical wall surface formed by recessing the bottom wall portion of the container into a hemispherical shape,
The movable member has a hemispherical convex spherical surface that fits and fits into the concave spherical surface,
The gas-containing component removing and sampling apparatus, wherein the second wall surface is formed of a convex spherical wall surface of the convex spherical surface of the movable member. In the gas content ingredient removal sampling device according to claim 2,
The first wall surface is composed of a horizontal upper wall surface formed by processing the bottom wall portion of the container into a horizontal shape,
The movable member has a horizontal lower wall surface formed by processing the lower surface in a horizontal shape so as to approach and separate while maintaining a parallel posture with respect to the horizontal upper wall surface,
The gas-containing component removing and sampling apparatus, wherein the second wall surface is constituted by the horizontal lower wall surface of the movable member. In the gas content ingredient removal sampling device according to claim 1,
The gas inlet portion is provided on the upper end portion side of the tube having the lower end opened, the gas inlet portion is positioned outside the container, and the lower end portion is positioned at a desired position on the bottom side in the container. A tube for gas transportation that is detachable and can be fixed in place;
A movable housing provided to be movable in the vertical direction while forming a cylindrical gap for forming a gas transport passage between the inner wall surface of the tubular body and penetrating the tubular body;
The first wall surface is formed on a fixing member provided to be fixed to the lower end of the gas transport tube,
The second wall surface is formed on a movable member provided to be fixed to a lower end of the movable casing,
2. The apparatus according to claim 1, wherein the movable housing is manually moved up and down by the operation means to adjust the passage width of the flow passage and the opening of the gas outlet portion. Gas component removal sampling device. In the gas content ingredient removal sampling device according to claim 5,
The fixing member has an inverted conical tapered outer wall surface with a taper that allows the upper end portion to communicate with the lower end of the gas transport pipe body, opens the lower end, and gradually decreases in diameter from the upper end side toward the lower end. It has a fixed cylindrical body having a generally inverted conical shape,
The first wall surface is configured by the tapered outer wall surface of the fixed cylindrical body,
The movable member has a substantially inverted conical movable cylinder having an inverted conical tapered inner wall surface that closes the lower end side and opens the upper end and fits and fits the tapered outer wall surface of the fixed cylindrical body. Configured with a body,
The gas-containing component removing and sampling apparatus, wherein the second wall surface is formed by the tapered inner wall surface of the movable cylindrical body. In the gas content ingredient removal sampling device according to claim 5,
The fixing member has a conical tapered inner wall surface with a tapered conical inner wall having a tapered end that communicates with an upper end portion of the tube for gas transportation and that has a lower end opened and that gradually increases in diameter from the upper end side toward the lower end. A fixed cylindrical body having a shape,
The first wall surface is constituted by the tapered inner wall surface of the fixed cylindrical body,
The movable member is configured to have a substantially conical movable conical body having a conical tapered outer wall surface that closes an upper end portion and fits and fits into the tapered inner wall surface of the fixed cylindrical body. ,
The gas-containing component removing and sampling apparatus, wherein the second wall surface is configured by a tapered outer wall surface of the movable conical body. In the gas content ingredient removal sampling device according to claim 5,
The fixing member has a fixed plate-like body of a desired size having a horizontal lower wall surface formed by processing the lower surface horizontally.
The first wall surface is constituted by the horizontal lower wall surface of the fixed plate-like body,
The movable member has a movable plate-like body having a horizontal upper wall surface formed by processing the upper surface in a horizontal shape so as to approach and separate while maintaining a parallel posture with respect to the horizontal lower wall surface. Configured
The second wall surface is constituted by the horizontal upper wall surface of the movable plate-like body.

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